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Citation for published version:Templeman, I, Gonzalez, J, Thompson, D & Betts, JA 2020, 'The Role of Intermittent Fasting and Meal Timing inWeight Management and Metabolic Health', Proceedings of the Nutrition Society, vol. 79, no. 1, pp. 76-87.https://doi.org/10.1017/S0029665119000636
DOI:10.1017/S0029665119000636
Publication date:2020
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Download date: 25. Oct. 2020
Title The Role of Intermittent Fasting and Meal Timing in Weight
Management and Metabolic Health
Authors Iain Templeman 1
Javier T. Gonzalez 1
Dylan Thompson 1
James A. Betts 1
Affiliations 1 – Department for Health, University of Bath, BA2 7AY, UK.
Corresponding Author James A. Betts ([email protected])
Brief Title Intermittent Fasting & Health
Keywords Eating Pattern, Circadian Rhythms, Time Restricted Feeding,
Weight Loss
Word Count 6936
Acknowledgements None 1
Financial Support I.T. was supported in writing this review by a PhD studentship 2
awarded by the University of Bath. 3
Conflicts of Interest J.T.G has received funding from The European Society for 4
Clinical Nutrition & Metabolism (ESPEN), The Rank Prize 5
Funds, Kenniscentrum Suiker & Voeding, Arla Foods 6
Ingredients, the Medical Research Council (MRC), the 7
Biotechnology & Biological Sciences Research Council 8
(BBSRC), PepsiCo and Lucozade Ribena Suntory. D.T. has 9
received funding from Unilever. J.A.B. has received funding 10
from the BBSRC, GlaxoSmithKline, Lucozade Ribena Suntory, 11
Kellogg’s, Nestlé and PepsiCo and is a scientific advisor to the 12
International Life Sciences Institute (ILSI). 13
14
Abstract 15
Obesity remains a major public health concern and intermittent fasting is a popular strategy 16
for weight-loss, which may present independent health benefits. However, the number of diet 17
books advising how fasting can be incorporated into our daily lives is several orders of 18
magnitude greater than the number of trials examining whether fasting should be encouraged 19
at all. This review will consider the state of current understanding regarding various forms of 20
intermittent fasting (e.g. 5:2, time-restricted feeding and alternate-day fasting). The efficacy 21
of these temporally defined approaches appears broadly equivalent to that of standard daily 22
calorie restriction, although many of these models of intermittent fasting do not involve fed-23
fasted cycles every other 24-h sleep-wake cycle and/or permit some limited energy intake 24
outside of prescribed feeding times. Accordingly, the intervention period therefore may not 25
regularly alternate, may not span all or even most of any given day, and may not even 26
involve absolute fasting. This is important because potentially advantageous physiological 27
mechanisms may only be initiated if a post-absorptive state is sustained by uninterrupted 28
fasting for a more prolonged duration than applied in many trials. Indeed, promising effects 29
on fat mass and insulin sensitivity have been reported when fasting duration is routinely 30
extended beyond 16 consecutive hours. Further progress will require such models to be tested 31
with appropriate controls to isolate whether any possible health effects of intermittent fasting 32
are primarily attributable to regularly protracted post-absorptive periods, or simply to the net 33
negative energy balance indirectly elicited by any form of dietary restriction. 34
Background 35
Obesity is a prevalent health concern throughout the world (1,2), which arises due to chronic 36
positive energy balance (3–5). Any energy surplus is stored primarily in the form of 37
triglycerides within adipocytes, thus leading to adipose tissue expansion (6,7) predominantly 38
as a result of adipocyte hypertrophy (8). If sustained over time, this hypertrophic expansion 39
can lead to adipocyte dysfunction, hyperglycaemia, hyperlipidaemia, ectopic lipid deposition, 40
chronic low-grade systemic inflammation and insulin resistance (9–15), thereby fostering 41
comorbidities such as type 2 diabetes and cardiovascular disease (16,17). To remedy this 42
metabolic dysfunction, interventions often seek to redress the underlying energy imbalance 43
by reducing energy intake and/or increasing expenditure, which can improve health outcomes 44
(18,19). However, these improvements are hampered by compensatory changes in appetite 45
and energy use (4,20–22), as well as poor adherence (23,24), resulting in poor long-term 46
success rates (4,25,26). 47
Strategies that exploit nutrient timing as a means of achieving weight loss and/or improving 48
metabolic health have been the subject of considerable public interest in recent years (27). 49
Intermittent fasting is an umbrella term that may be used to describe these approaches, which 50
involve a complete or partial restriction of energy within defined temporal windows on a 51
recurrent basis (27,28). Thus far, the therapeutic potential of intermittent fasting has been 52
largely overshadowed by direct manipulation of the principal components of the energy 53
balance equation (29). However, advances in the understanding of circadian rhythms suggest 54
that this could be a particularly effective approach for tackling obesity and the accompanying 55
dysfunction (30,31), in addition to arguably being more acceptable in practice than 56
conventional alternatives (32–36). To explore this notion, this review will consider the 57
literature on meal timing and intermittent fasting as it relates to metabolic health. 58
Meal Timing 59
In Western cultures, a pattern of three or more meals per day is generally accepted as a 60
societal norm (37,38). However, this typically results in an anabolic state predominating each 61
day (39,40). The postprandial metabolic response to a mixed-macronutrient meal in 62
metabolically healthy participants is characterised by a peak in glycaemia within the first 63
hour followed by a steady return to fasted glycaemia over the ensuing two hours (41,42). This 64
is paralleled by an accompanying peak in insulin secretion within the first hour followed by a 65
decrease over the next 4 hours (42). Conversely, plasma triglyceride concentrations rise 66
steadily to a peak after 3-5 hours and generally remain 50% higher than baseline even after 6 67
hours (41). When a subsequent meal is ingested approximately five hours after the first (as is 68
common in Western diets), glucose peaks at a similar time after feeding, albeit an attenuated 69
absolute peak (43). However, glucose then takes slightly longer to return to baseline as the 70
day progresses, a pattern that is largely mirrored by insulin concentrations (44). Plasma 71
triglycerides on the other hand do not reach their peak following the first meal until shortly 72
after the second meal is ingested, then fall rapidly due to the insulinaemic response to the 73
second meal, before peaking again around 5 hours after the second meal (44). 74
These responses suggest that, even with just two meals per day, plasma triglycerides are 75
elevated continuously for 12 hours, with this pattern then propagated when further extended 76
to include a third meal. This is well-demonstrated by Ruge et al. (45), who examined the 24-77
hour circulating profiles of glucose, triglycerides and insulin in response to three successive 78
meals at 10:00, 15:00 and 20:00. Within this model, triglycerides remained elevated until 79
02:00, along with insulin and glucose concentrations. Similarly, McQuaid et al. (46) showed 80
that triglyceride extraction by adipose tissue in response to three meals per day is elevated for 81
over 16 hours. The net effect of this is that the majority of each 24-h day is spent in a 82
postprandial and lipogenic state, which is conducive to fat accretion (39,40). By extension, 83
this provides fewer opportunities for net lipolysis and the predominance of lipid-derived 84
substrates in energy metabolism, thereby favouring positive fat balance. 85
Ultimately, this results in a scenario wherein those adhering to conventional dietary meal 86
timing patterns are attempting to achieve energy balance using a feeding schedule that is 87
inherently biased toward fat accretion. Conventional diet and exercise interventions aim to 88
reduce the amplitude of postprandial excursions in order to provide more opportunities for 89
the liberation and utilisation of endogenous lipid reservoirs. However, the imbalance between 90
the daily fasting window and the daily feeding window remains largely unperturbed. 91
Comparatively, the omission of meals is typically necessitated by intermittent fasting and 92
eliminates a subset of these postprandial excursions, thereby providing greater equilibrium 93
between fasting and feeding opportunities and a better platform for achieving energy balance. 94
Further to this, the routine extension of fasting periods has been associated with metabolic 95
benefits which are independent of net energy balance (27,28,47), constituting a secondary 96
therapeutic dimension to these strategies. Specifically, Anton et al. (28) argue that the 97
depletion of hepatic glycogen reserves and the ensuing transition toward metabolism of 98
endogenous, lipid-derived substrates (i.e. non-esterified fatty acids, glycerol, ketone bodies), 99
prompts a series of adaptive processes conducive to improved health outcomes, including 100
improvements in body composition and insulin sensitivity. Considering that this transition 101
does not take place in most instances until the uninterrupted fasting duration proceeds beyond 102
12-14 hours (28,48), these adaptive processes are not often invoked by the conventional meal 103
patterns described above. 104
Based on the above reasoning, it is conceivable that intermittent fasting may constitute an 105
efficacious strategy for tackling obesity and the metabolic disorders associated with excess 106
adiposity. To date, however, studies exploring these facets of intermittent fasting are scarce 107
and inconsistent. 108
Eating Frequency 109
Perhaps the most widely researched dimension of nutrient timing within the context of 110
obesity in humans is eating frequency. Early work by Fabry et al. (49) deployed a cross-111
sectional approach to explore the relationship between intake frequency and metabolic health. 112
Interestingly, in a cohort of 440 men, higher eating frequency broadly corresponded to a 113
healthier profile of body mass index (BMI), cholesterol concentrations and fasting glucose. 114
Contrary to this, using data from NHANES, Murakami and Livingstone (50) observed that 115
those eating on more than four occasions per day were approximately 50% more likely to be 116
overweight or obese by BMI relative to those eating on less than three occasions per day. 117
Such discrepancies are a consistent theme throughout these cross-sectional studies; a recent 118
systematic review by Canuto et al. (51) analysed data from 31 such studies containing a 119
collective sample of over 130,000 participants. Of these 31 studies, 14 established an inverse 120
association, 10 showed no association, and 7 revealed a positive association, which the 121
authors ascribe to the spectrum of approaches employed. 122
Upon shifting to prospective methodologies, the pattern appears to be largely the same; two 123
recent systematic reviews conclude that the majority of studies reveal no association between 124
eating frequency and subsequent obesity (52,53). The review of Raynor et al. (52) makes a 125
particularly strong case, given that these authors only included human studies in which food 126
was provided or intake monitored in a laboratory setting. However, of the studies covered in 127
these reviews, most evaluated the impact of increased meal frequency on metabolic health, 128
wherein three meals per day is used as the reference for lower frequency. Therefore, upon 129
framing these studies within the context of the 24-hour metabolite profiles discussed 130
previously, the lack of a consensus is perhaps not surprising. In fact, only one of the studies 131
reported is likely to have resulted in the predominance of a fasting state over the course of 24 132
hours (54). 133
Specifically, the study of Stote et al. (54) explored the impact of reducing meal frequency to 134
one meal per day under conditions of energy balance. Briefly, 15 normal-weight participants 135
completed two 8-week intervention periods in a randomised crossover design with an 11-136
week washout interval. In one treatment, all calories were consumed in a single meal between 137
17:00 and 21:00, whilst the other treatment separated the same foods into a conventional 138
breakfast, lunch and dinner format. To facilitate compliance, the dinner in both conditions 139
was consumed under supervision and all foods were provided. The diets were matched for 140
both energy and macronutrient content and targeted weight maintenance, with daily 141
adjustment of prescribed intake based on body weight measurements, which were then 142
mirrored in the opposing trial. No differences in body mass, body composition or health 143
markers were apparent at the outset of each treatment and no differences in energy intake, 144
macronutrient balance or physical activity were noted between the two conditions. Despite 145
these null findings, body mass and fat mass (as assessed by bioelectrical impedance) were 146
reduced by 1.4 kg and 2.1 kg, respectively, following the one meal per day condition but not 147
the three meals per day condition. However, the reduction in adiposity was not accompanied 148
by improvements in lipid profile or glycaemia (55). This is consistent with the prior 149
suggestion that extending the daily fasting period may result in increased utilisation of lipid-150
derived substrates in energy metabolism and favourable effects on fat balance (28). 151
The above interpretation suggests that, in much the same way as a protracted daily feeding 152
window may be conducive to an energy surplus, prolonged fasting on a routine basis could be 153
an effective strategy to counter fat accretion. However, what is particularly interesting here is 154
that this observation was made under carefully matched conditions. Whilst this does not 155
exclude any possibility of some amalgamation of undetectable changes in the various 156
components of energy balance (56), it is also plausible that the protracted fasting period is 157
exerting impacts on energy metabolism that are independent of net energy balance (28,57). 158
The current literature on intermittent fasting provides a useful platform for exploring this 159
notion further. 160
Intermittent Fasting 161
The umbrella term intermittent fasting refers to a series of therapeutic interventions which 162
target temporal feeding restrictions, nominally categorised as: the 5:2 diet, modified 163
alternate-day fasting, time-restricted feeding and complete alternate-day fasting (27). 164
Irrespective of the rationale for each, such approaches have been subject to growing 165
popularity in recent years, yet experimental data to support their application is comparatively 166
sparse (27,36). Bluntly, the number of diet books advising how intermittent fasting can be 167
incorporated into our daily lives is several orders of magnitude greater than the number of 168
scientific papers examining whether intermittent fasting should be encouraged at all (27). 169
The 5:2 Diet – Amongst the most coveted forms of intermittent fasting is the 5:2 diet, 170
wherein severe energy restriction is imposed on two days per week with ad libitum 171
consumption on the remaining five. The study of Carter, Clifton and Keogh (58) randomised 172
63 adults with overweight or obesity and type 2 diabetes to 12 weeks of either daily calorie 173
restriction or a 5:2 approach. The 5:2 group reduced their intake to 400-600 kcal for two non-174
consecutive days per week and followed their habitual diet on the remaining five, whilst the 175
daily restriction group simply reduced their intake to 1200-1550 kcal everyday. Although the 176
extent to which prescriptions were achieved was not reported, main effects of time but not 177
group were seen for reductions in body mass, fat mass and fat-free mass, as well as 178
improvements in glycated haemoglobin concentration and the use of diabetic medications. 179
Similar conclusions were also drawn by two recent studies which compared this 5:2 approach 180
(i.e. 400-600 kcal∙day-1 on two non-consecutive days per week) against daily energy 181
restriction over 6 months (59,60). 182
This pattern of results indicates a broad equivalency between the metabolic impacts of the 5:2 183
diet versus daily calorie restriction, arguing against any special properties of the fasting 184
element per se. However, this is not a consistent finding throughout the literature. Upon 185
comparing the 5:2 approach (requiring two consecutive days of 75% calorie restriction per 186
week) against daily calorie restriction (requiring 25% calorie restriction everyday) over six 187
months, Harvie et al. (61) observed differential changes in fasting insulin and fasting indices 188
of insulin resistance. Despite similar reductions in body mass and fat mass, the modest 189
reductions in fasting insulin and insulin resistance seen in both groups were more pronounced 190
with the 5:2 method. Although this may reflect a more potent influence of using two 191
consecutive days of severe energy restriction (as opposed to non-consecutive), there were 192
also greater reductions in energy and carbohydrate intake in this group, which complicate the 193
interpretation. 194
Using a similar approach, Antoni et al. (62) sought to compare the effects of intermittent 195
energy restriction (implemented using the 5:2 approach) against daily calorie restriction when 196
matched for net energy balance and thus weight losses, in order to minimise the confounding 197
influence of such factors on metabolic health. Furthermore, this study featured dynamic 198
indices of metabolic control, building upon the prior studies which only featured fasted 199
measures. Briefly, 27 participants with overweight or obesity were randomised to undertake 200
either an intermittent or a continuous energy restriction diet. The 5:2 condition restricted 201
participants to 630 kcal∙day-1 for two consecutive days each week, with a self-selected 202
eucaloric diet on the remaining five. Comparatively, the continuous restriction implemented a 203
self-selected diet intended to reduce energy intake by 600 kcal∙day-1. As opposed to returning 204
to the laboratory after a fixed period, participants were reassessed upon achieving a 5% 205
weight loss. Despite larger reductions in energy intake in the intermittent condition, the 206
design meant that changes in body mass were similar between groups. Body composition and 207
fasting biochemical outcomes were also similarly affected by the two diets, showing good 208
agreement with previous studies. However, the intermittent diet resulted in significant 209
reductions in postprandial triglyceride concentrations relative to daily calorie restriction, 210
whilst postprandial C-peptide concentration also showed a tendency for greater reductions in 211
the intermittent feeding group. The authors concluded that this highlights a potential 212
superiority of intermittent relative to continuous energy restriction. 213
Based on the above studies of the 5:2 approach to intermittent fasting, it seems that the 214
manner in which the fast is applied is a key determinant of the impacts on metabolic health. 215
When the fast is undertaken on consecutive days, there is an apparent superiority relative to 216
daily calorie restriction (61,62), whilst applying the fast on non-consecutive days results in 217
broadly equivalent effects (58–60). Upon considering this in terms of the resultant 218
uninterrupted fasting duration, this would appear to fit with the proposition of Anton et al. 219
(28), as fasting on consecutive days is more likely to result in an uninterrupted fast of over 220
12-14 hours when compared to fasting on non-consecutive days. However, as these 221
interventions do not confine the permitted intake during fasting to a specific time window 222
(e.g. 400-600 kcal consumed between 12:00 and 14:00 on fasting days), this makes it difficult 223
to establish the exact duration of absolute fasting achieved. 224
Modified Alternate-Day Fasting – The majority of human studies which examine 225
intermittent fasting have centred upon a strategy referred to as modified alternate-day fasting 226
(27). It differs from the 5:2 diet in two key regards: the severe restriction is applied during 227
alternating days (nominally 24 hours, although practically more varied to accommodate 228
sleep); and any permitted calories during ‘fasting’ are provided as a single meal (thereby 229
ensuring a tangible extension of the typical overnight fast). Much of the work undertaken in 230
this field originates from pioneering experiments by Varady and colleagues, in which 231
participants were required to alternate between 24-hour periods of fasting and ad libitum 232
feeding, with a single 600-800 kcal meal permitted between 12:00 and 14:00 on non-feeding 233
days. 234
The effects of this approach on body mass were initially explored by Varady et al. (32) in a 235
single-arm trial, where 12 obese participants completed 8 weeks of modified alternate-day 236
fasting. Reported adherence to the fasting protocol remained high throughout, with energy 237
intake averaging 26% of habitual (32,35). Comparatively, intake on feeding days reached 238
95% of the habitual level, resulting in a 37% net calorie restriction on average. This led to 239
body mass losses of 5.6 kg, 5.4 kg of which was accounted for by decreases in fat mass (32). 240
Total cholesterol, LDL cholesterol and triglycerides were also reduced by at least 20%, 241
effects which were associated with improvements in adipokine profile (63). Subsequent work 242
by the same group neatly demonstrates that these outcomes are similar when applied to 243
cohorts of adults who are overweight (64), when meal timing on the fasting day can be varied 244
(65), and that concurrent macronutrient manipulation does not exert additive effects (66). 245
Collectively, these data suggest that modified alternate-day fasting may be a viable means of 246
improving cardiometabolic health in adults who are overweight or obese. However, without a 247
comparative daily calorie restriction group it is difficult to isolate any independent effects of 248
the fasting periods from the effects of energy restriction and/or associated weight loss. This 249
was addressed recently by a comparison of the two methods under isocaloric conditions 250
relative to a no intervention control group (67,68). Briefly, 69 adults with obesity were 251
randomised to undertake 6 months of modified alternate-day fasting or daily calorie 252
restriction. The alternate day fasting diet restricted participants to a single meal containing 253
25% of their measured energy requirements between 12:00 and 14:00 during fasting periods, 254
but prescribed 125% of energy requirements on feeding days. Conversely, the daily calorie 255
restriction diet prescribed a 25% reduction in energy intake every day, resulting in an 256
equivalent reduction in energy intake of 25% in both groups. Macronutrient balance was 257
preserved in both instances and the attained calorie restriction was 21% and 24% for 258
alternate-day fasting and daily calorie restriction, respectively. The observed body mass loss 259
of 6.8 % was also similar between the two groups, a pattern driven by changes in both fat 260
mass and lean mass. Fasted markers of metabolic health were also largely unaffected by 261
either intervention, including lipid profile, inflammatory markers, adipokines, glucose 262
concentration and insulin resistance (67,68). Furthermore, few differences emerged during an 263
ensuing 6-month weight maintenance period in which the feeding patterns were maintained 264
but the prescriptions modified to fulfil energy requirements (i.e. no energy deficit). 265
This once again indicates that intermittent fasting and daily calorie restriction exert similar 266
effects on most health outcomes, as concluded previously for the 5:2 approach. However, 267
during the modified alternate-day fasting intervention, participants consistently over-268
consumed on fasting days and under-consumed on fed days, in what the authors describe as 269
de facto calorie restriction (67). Consequently, over the duration of the study the difference in 270
reported energy intake between feeding and fasting days was less than 500 kcal on average 271
(69). Yet when the 34 participants that undertook alternate-day fasting were stratified into 272
those who lost more versus less than 5% body mass, those closest to the prescribed intake 273
targets showed larger decreases in body mass despite consuming more calories overall (69). 274
Unfortunately, the mechanisms underpinning this are unclear. The observation could reflect 275
increased use of lipid-derived substrates or lower levels of adaptive thermogenesis with 276
intermittent methods, or perhaps it simply reflects poorer dietary reporting by those with 277
lower adherence. 278
Nonetheless, data emerging from studies of modified alternate-day fasting do not allude to a 279
superiority relative to daily calorie restriction. Although, the use of single-arm trials and poor 280
adherence to fasting prescriptions leave this question open to further study. 281
Time-Restricted Feeding – Ironically, the adherence issues that appear common to modified 282
alternate-day approaches may lie in the imposition of a severe restriction as opposed to a 283
complete fast, which in being an absolute (albeit more severe) could in fact facilitate 284
compliance (32,33,36). Drawing from this premise, time-restricted feeding is another method 285
of intermittent fasting which has emerged recently (27) and requires no knowledge of food 286
composition or restraint at eating occasions, only awareness of the time at which eating 287
occasions are permitted at all. This approach aims to restrict food intake to a temporal 288
window (typically ≤10 h) within the waking phase, thereby reducing feeding opportunities 289
and extending the overnight fast to at least 14 hours per day (70). 290
Work in our laboratory explored the impact of extending the overnight fast on energy balance 291
and nutrient metabolism, thereby providing several insights regarding the effects of such 292
strategies (71–74). Initially, 33 adults who were of healthy weight were randomised to 6 293
weeks of either consuming breakfast, defined as at least 700 kcal before 11:00 daily (with 294
half consumed within 2 hours of waking), or extended morning fasting up until 12:00 (73). 295
Interestingly, improvements in anthropometric parameters and fasting health markers were 296
not meaningfully different between interventions. In agreement, a panel of hormones 297
implicated in the regulation of energy balance showed little change following the two 298
interventions, although specific measures of adipose tissue insulin sensitivity suggested an 299
improvement in the breakfast group only (71). 300
These largely null findings relative to prior research could be explained by the free-living 301
approach used to study compensatory changes in components of energy balance. The fasting 302
group consumed fewer calories than the breakfast group when averaged throughout each 24-303
hour period, but this was compensated for by lower physical activity thermogenesis. Upon 304
applying this protocol to a cohort of adults with obesity (72), extended fasting resulted in a 305
slightly greater compensatory increase in energy intake following fasting (although still not 306
adequate to offset the energy consumed or omitted at breakfast), whilst daily fasting was 307
again causally related to lower physical activity energy expenditure in the morning. 308
Interestingly, in this cohort with obesity breakfast did result in improved insulinaemic 309
responses during an oral glucose tolerance test relative to the fasting condition. However, this 310
test was aligned for circadian cycle rather than feeding cycle, so the observed finding could 311
simply reflect better alignment with anticipated events in the breakfast condition. 312
Other studies have applied time-restricted feeding under eucaloric conditions, much alike the 313
study of Stote et al. (54). Focusing on energy metabolism, Moro et al. (75) randomised 34 314
men to 8 weeks of time-restricted feeding or a control diet. Diets were matched for energy 315
and macronutrient content and aimed to provide 100% of energy requirements across three 316
meals in both conditions. In the control condition, meals were consumed at 08:00, 13:00 and 317
20:00, whilst in the experimental condition meals were consumed at 13:00, 16:00 and 20:00 318
to give a 16-hour fast. The time-restricted approach resulted in reductions in fat mass relative 319
to controls, which were partnered by decreases in respiratory exchange ratio, indicating a 320
shift toward fat oxidation. Interestingly, however, despite accompanying reductions in leptin 321
and hypothalamic-pituitary-thyroid signalling, resting energy expenditure was maintained. 322
This reinforces the notion that nutrient timing impacts upon nutrient metabolism, whilst also 323
highlighting that this appears to occur to a greater degree with a 16-hour fast relative to a 12-324
hour fast. Considering this in light of the typical postprandial nutrient profile discussed 325
previously, the increase in fasting duration may provide more opportunities for metabolism of 326
substrates derived from endogenous lipids. This again points to the possibility that routine 327
extension of the fasting period beyond 12-14 hours may be key to these benefits, which was 328
not necessarily achieved by the 5:2 or modified alternate-day methods discussed earlier. The 329
pivotal question is whether these improvements are enhanced with even longer durations of 330
complete fasting. 331
More prolonged and complete fasting was recently examined by Sutton et al. (70), who 332
hypothesised that circadian rhythms in energy metabolism would potentiate the effects of 333
time-restricted feeding when eating times are confined to earlier stages of the waking phase. 334
Using a repeated-measures crossover design, they compared the effect of consuming all daily 335
calories within a 6-hour window and a 12-hour window over 5 weeks in men with pre-336
diabetes. The diets were prescribed based on energy requirements to maintain energy balance 337
and were also matched for energy and macronutrient content. Compliance to the two 338
conditions was high and the extended fasting period was accompanied by reductions in 339
fasting insulin, peak insulin and insulin resistance during an oral glucose tolerance test. 340
However, it appears the magnitude and persistence of any treatment effects may have 341
required a longer wash-out interval between repeated treatments, as the impacts on 342
insulinaemia were seemingly affected by baseline differences arising from a trial order effect. 343
Combined with the fact that the fasting duration preceding post-intervention measurements 344
was not standardised across trials, further investigations are warranted to verify these 345
intriguing possibilities. 346
Based on all the above findings, evidence does point to an effect of extended fasting intervals 347
on fat mass independent of energy balance, particularly when the fasting interval is extended 348
to at least 16 hours, as shown by Stote et al. (54) and Moro et al. (75). In both cases, this 349
produced significant reductions in fat mass relative to a routine 12 hour fast, which implicates 350
extended fasting beyond 12 hours as a key factor. However, the importance of such changes 351
for metabolic health are less clear due to a series of confounding influences. 352
Complete Alternate-Day Fasting – Thus far, the intermittent fasting strategies discussed 353
typically permit the consumption of calories within each 24-hour cycle to some degree, 354
meaning that the fasting interval is only extended by a few hours (76). This is primarily to 355
facilitate adherence (32,34) but it also replenishes hepatic glycogen stores and reduces the 356
utilisation of lipid-derived substrates (i.e. ketone bodies), which may mask several proposed 357
benefits of intermittent fasting (28). Furthermore, this disruption is profoundly asymmetric, 358
in that even a short feeding occasion immediately suppresses lipolysis and ketogenesis, which 359
then do not return for a number of hours (41,42). It is worthy of note at this juncture that the 360
inclusion of physical activity or exercise during the fasted period may serve to accelerate the 361
restoration of these pathways to some degree, although the concurrent application of 362
intermittent fasting alongside exercise interventions is beyond the scope of this review. 363
Nonetheless, the 20-hour fasting interval used by Stote et al. (54) is likely to have led to a 364
greater reliance on these lipid-derived substrates over the course of 24 hours, which may 365
explain the reduction in fat mass despite eucaloric intake. 366
Building upon this premise, Halberg et al. (47) applied a 20-hour fast on alternate days from 367
22:00 to 18:00, representing an integration of the strategies employed by Stote et al. (54) and 368
Varady et al. (32). Fasting prohibited all intake with the exception of water, whilst during the 369
intervening feeding periods participants were told to double their habitual intake to maintain 370
body mass. Although dietary intake was not monitored, blood samples collected in a subset 371
of fasting periods confirmed compliance with the fasting protocol, with corresponding 372
changes in systemic concentrations of glucose, non-esterified fatty acids, glycerol, 373
adiponectin and leptin. Although both body mass and fat mass were unchanged, the glucose 374
infusion rate during a euglycaemic-hyperinsulinemic clamp increased in the final 30 minutes 375
of the sampling period, suggesting enhanced insulin sensitivity following complete alternate-376
day fasting. Accordingly, this was accompanied by more rapid suppression of adipose tissue 377
lipolysis during the insulin infusion. While the lack of an effect on body mass and fat mass 378
relative to prior studies may reflect the disparity in cumulative fasting time, the authors were 379
nonetheless able to conclude that this approach to intermittent fasting can improve metabolic 380
health even in the absence of detectable changes in body mass. 381
Employing a similar approach, Soeters et al. (77) recruited eight males of healthy weight to a 382
repeated-measures crossover study. This compared the effects of two weeks of a standard 383
weight maintenance diet against two weeks of an intermittent fasting diet, using the same 384
fasting protocol as Halberg et al. (47). In this instance, a more prescriptive approach was 385
adopted to the feeding cycles, with liquid meals used to bolster intake and adjustment of 386
prescriptions in the event of meaningful weight change. Accordingly, body mass and 387
composition were unaltered, yet there were no significant changes in glucose, lipid or protein 388
kinetics in the basal state, or during a two-stage euglycaemic-hyperinsulinemic clamp. In 389
actuality, the only difference was a slight decrease in resting energy expenditure following 390
the intermittent fasting arm. 391
To the contrary of Halberg et al. (47) and Stote et al. (54), the above findings suggest that 392
recurrent extension of the fasting period exerts no influence on energy or nutrient 393
metabolism, aside from a possible decline in resting energy use. Whilst there are some 394
discrepancies in terms of the approach to feeding cycles and assessment of nutrient 395
metabolism under dynamic conditions, attributing to such factors would suggest the effect is 396
unlikely to be clinically meaningful. However, work by Heilbronn and colleagues provides 397
interesting insights that could explain such stark contrasts between ostensibly similar 398
approaches (34,78). Their study applied an intermittent fasting intervention to a cohort of 16 399
adults who were not obese which involved fasting from midnight to midnight on alternating 400
days for 3 weeks, with fasting periods only permitting energy-free drinks and sugar-free gum 401
(fed periods were ad libitum). Assessments of body composition, a mixed-meal test and 402
muscle biopsies were carried out at baseline and follow-up, with an additional set of 403
measurements collected after a 36-hour fast to explore the physiological impact of individual 404
fasting periods on energy metabolism. 405
Although energy intake was not reported, the intervention reduced body mass by 2.5%, 406
approximately two thirds of which was accounted for by reduced fat mass. However, the 407
majority of fasting parameters, including plasma glucose concentration, resting metabolic 408
rate, substrate oxidation and muscle GLUT4 content showed no notable change (34,78). Key 409
exceptions were sex-specific alterations in cholesterol profile, with women experiencing an 410
increase in HDL cholesterol concentration and men exhibiting reductions in fasting 411
triglycerides. Values collected after 36 hours of fasting confirmed increased fatty acid 412
oxidation, raising the question of why the routine upregulation of fat metabolism combined 413
with body mass losses resulted in no consistent changes in metabolic health. However, this 414
pattern of sexual dimorphism continued into postprandial outcomes, with increases in glucose 415
area under curve for females and reductions in insulin area under curve for males (78). 416
It might then be suggested that males and females respond differently to complete alternate-417
day fasting. However, there were a number of baseline differences between men and women 418
in that study which should be considered in this interpretation, with men exhibiting higher 419
glucose, insulin and triglyceride concentrations in the fasted state (34). Upon contextualising 420
this in the physiology of insulin resistance (9–14), it seems plausible that the metabolic state 421
of male participants at baseline may stand to benefit more from the routine extension of 422
fasting (notwithstanding the possibility of statistical regression). In these individuals, the shift 423
toward fat oxidation seen in response to prolonged fasting could help to clear lipid 424
intermediaries from non-adipose tissues, thereby enhancing insulin sensitivity. This is 425
supported by the reported increase in CPT1 protein content in muscle tissue after the 426
intervention (78,79). 427
Extending this premise to the studies of Halberg et al. (47) and Soeters et al. (77), the 428
average body fat percentage of their cohorts was 20.1% and 14.8%, respectively. This may 429
therefore support the notion that those with lower levels of adiposity may not benefit from 430
such interventions. Consequently, it is imperative to consider the seemingly distinct 431
responses seen between leaner and more overweight cohorts when interpreting the results of 432
similar studies. This is not only because the potential for weight loss and health gain may 433
vary, but also because the presentation as lean or obese at baseline may be symptomatic of a 434
predisposition towards various compensatory adjustments that predict responsiveness to 435
treatment (5, 72–74,80). 436
Furthering this line of enquiry, Catenacci et al. (81) undertook a randomised controlled trial 437
of complete alternate-day fasting in a sample of adults with obesity. Briefly, 26 participants 438
were randomised to undertake 8 weeks of either daily calorie restriction (requiring a 439
reduction in energy intake of 400 kcal∙day-1) or a complete alternate-day fast. The 440
intermittent fasting condition imposed a fast on every other day and provided a diet to meet 441
estimated daily energy requirements during feeding periods, with a series of 200 kcal 442
optional food modules to permit ad libitum intake. All foods were provided and diets were 443
matched for macronutrient balance rather than energy intake. Consequently, energy intake 444
across the intervention was lower with the intermittent fasting approach, averaging 53% of 445
weight maintenance requirements compared to 72% for daily calorie restriction. This was 446
accompanied by a trend for greater reductions in body mass with intermittent fasting relative 447
to calorie restriction, with 8.8% and 6.2% reductions seen in the respective conditions. 448
Despite this, fat mass and lean mass decreased to a similar degree in both groups, a pattern 449
mirrored by improvements in fasted lipid profile. Only intermittent fasting produced 450
improvements in fasted glucose concentration from baseline to follow-up, yet responses to a 451
dynamic test of insulin sensitivity were unaltered. Conversely, resting metabolic rate was 452
reduced by daily calorie restriction only, following correction for body composition changes, 453
with a trend for a between-group difference. However, between-group comparisons were 454
compromised by baseline differences, with those in the daily calorie restriction group 455
presenting with higher body mass and fasting insulin concentrations on average. 456
Summary 457
Intermittent fasting clearly encompasses a broad spectrum of dietary interventions. The 458
defining characteristic is the confinement of calorie restriction to a specified temporal 459
window, be that 16 hours each day (75), every other day (32,34), or just two days per week 460
(61,62). Across these various models, intermittent fasting can elicit reductions in body mass 461
and improvements in metabolic health, effects which appear broadly comparable to standard 462
daily calorie restriction (82). However, because the therapeutic potential of these temporal 463
strategies may lie in routinely extending catabolic periods, thereby increasing reliance on 464
lipid-derived substrates (28), the similar efficacy in relation to standard approaches could 465
instead reflect a failure to meaningfully extend the post-absorptive period. The 5:2 diet and 466
modified alternate-day fasting rarely omit more than one meal in sequence and therefore this 467
transition to lipid-derived substrates may scarcely be made (58–60,67,68). Conversely, if 468
applying approaches that extend the fasting interval toward 20 hours and beyond (e.g. 469
consecutive fasting days in the 5:2 diet or time-restricted feeding), this transition to lipid-470
derived substrates is likely to be made more frequently, perhaps explaining the proposed 471
superiority of these approaches (54, 61,62,75). Unfortunately, whilst the latter studies of 472
complete alternate-day fasting offer amongst the longest uninterrupted fasting periods, the 473
true effects of this are difficult to isolate due to metabolically diverse samples and the use of 474
single-arm trials. Consequently, there remains an urgent need for well-designed, randomised-475
controlled trials of this commonly adopted approach. 476
Future Directions 477
Identifying more effective strategies for managing obesity and associated metabolic disorders 478
remains a public health challenge and intermittent fasting may represent a potent tool. 479
However, research to support this is scarce and a number of important facets have been 480
overlooked. Further research is therefore warranted to establish whether intermittent fasting 481
is simply an alternative means of achieving calorie restriction (76), or a dietary strategy 482
which offers a favourable method for maintaining/improving metabolic health. 483
Body Composition – Whilst much investigation has been devoted to the effects intermittent 484
fasting exerts on fat balance, routinely extending catabolic periods also carries implications 485
for fat-free mass. Anton et al. (28) argue that the increased reliance on lipid-derived 486
substrates during prolonged fasting serves to minimise deteriorations in muscle mass and 487
function, although this does not negate these deteriorations all together. Mechanistically, net 488
protein balance is a product of constant interactions between protein synthesis and 489
breakdown (83). Following an overnight fast (approximately 8-12 hours), there is an increase 490
in amino acid efflux from muscle tissue (84), suggesting a shift in favour of net muscle 491
protein breakdown (85–87). Whilst there are limited data to support an exaggeration of this 492
catabolic state when the fasting duration is extended to 24 hours, a recent study by Vendelbo 493
et al. (88) showed that fasting for 72 hours doubled the rate of amino acid efflux from 494
skeletal muscle when compared to a 10-hour fast. Accordingly, it would be reasonable to 495
anticipate a greater decline in fat-free mass in response to intermittent fasting when compared 496
to daily calorie restriction. 497
Contrary to this mechanistic perspective, however, a systematic review of randomised-498
controlled trials by Varady (89) concluded that intermittent fasting may in fact offer 499
enhanced retention of fat-free mass when compared to daily calorie restriction. A similar 500
conclusion was also drawn by a more recent review comparing intermittent approaches with 501
very-low calorie dieting (90). Whilst the predominance of modified alternate-day fasting 502
studies in the former review may help to explain this, it is worthy of note that the complete 503
alternate-day studies of both Halberg et al. (47) and Heilbronn et al. (34) were included. If 504
verified, enhanced retention of fat-free mass relative to daily calorie restriction would be a 505
potent asset considering its association with resting metabolic rate (91–93). Consequently, 506
clarifying the effect of complete alternate-day fasting on fat-free mass should be a central 507
research priority. 508
Energy Expenditure – A key (but often overlooked) issue with conventional obesity 509
management approaches is compensatory changes in other dimensions of energy balance, 510
particularly decreased energy expenditure with daily calorie restriction (21,22,94). It is not 511
clear from the existing body of intermittent fasting research whether such compensatory 512
changes may be invoked. Focusing initially on resting metabolic rate, both Heilbronn et al. 513
(34) and Catenacci et al. (81) reported no detectable change in response to complete 514
alternate-day fasting, whilst Soeters et al. (77) suggest a decline in resting energy use of 59 515
kcal∙day-1. Conversely, physical activity energy expenditure has not been thoroughly and 516
objectively examined in response to complete alternate-day fasting. Klempel et al. (35) 517
observed no changes in daily step counts during 8-weeks of modified alternate-day fasting, 518
despite clinically meaningful weight losses, and ensuing studies employing accelerometers 519
have verified this outcome (95,96). However, it should be noted that these studies all 520
employed modified alternate-day fasting approaches, which can reasonably be expected to 521
differ in their effects on voluntary behaviour relative to complete alternate-day methods. 522
In the absence of objective measures of energy expenditure, Sutton et al. (70) argue that 523
energy expenditure is not affected by temporal restrictions of energy intake based on the 524
absence of significant differences in body mass in their eucaloric time-restricted feeding 525
study. However, Dhurandhar et al. (56) highlight that accurate determination of energy 526
balance necessitates measurement of all aspects of the equation. While it does then remain a 527
distinct possibility that typical compensatory responses to an energy deficit are blunted when 528
intermittent fasting, a lack of evidence about isolated dimensions of energy expenditure 529
currently prevents reliable conclusions being drawn. There is therefore definite need to 530
examine the cumulative impact of intermittent fasting on the components of energy balance 531
in a reliable and well-controlled manner, not least physical activity thermogenesis. 532
Postprandial Nutrient Metabolism – An opportunity arising from the pre-existing literature 533
stems from the fact that the majority of studies have focused on fasting measures of glucose, 534
insulin and triglycerides, with very few studies employing dynamic tests. The relevance of 535
this is well-illustrated by the impact of intermittent fasting on insulin; improvements in 536
fasting insulin have been consistently shown in a number of studies as reviewed by Barnosky 537
et al. (82). They also show that in a subset of these studies fasting indices of insulin 538
resistance such as the homeostasis model generally improve following a period of 539
intermittent fasting. However, it is important to note that while these fasting indices are 540
useful in easing experimental demands, there are several limitations. For instance, Borai et al. 541
(97) suggest it is possible for a participant to be insulin resistant without demonstrating 542
fasting hyperinsulinaemia. 543
The same inconsistencies emerge when examining postprandial glycaemia, whilst 544
postprandial lipaemia has been largely ignored. On an acute basis, Antoni et al. (98) 545
demonstrate that a day of 100% caloric restriction results in enhanced suppression of 546
postprandial triglyceride and non-esterified fatty acid concentrations, relative to habitual 547
intake and partial energy restriction. Extending this to the 5:2 approach, a similar pattern 548
emerged with improvements in postprandial triglyceride levels with the intermittent condition 549
relative to continuous restriction (62). Such effects are also consistent with the enhanced 550
suppression of adipose tissue lipolysis reported by Halberg et al. (47). Given the importance 551
of these outcomes in the context of obesity and the associated comorbidities, closer 552
examination is warranted. 553
Comparative Designs – Despite being proposed as an alternative approach to weight loss, 554
few human trials to date have directly compared complete alternate-day fasting against 555
standard daily calorie restriction. Although it is generally reported that the outcomes are 556
similar, the broad spectrum of cohorts and experimental protocols employed confounds 557
reliable comparisons against the pre-existing literature (89). The study of Catenacci et al. (81) 558
is certainly an exception to this pattern, as they directly compared complete alternate-day 559
fasting and daily calorie restriction; however, the two conditions were not matched for the 560
degree of calorie restriction imposed. For this reason, reaching a consensus on the relative 561
merits of intermittent fasting is not possible without further studies with appropriate controls. 562
Fasting-Dependent Effects – Lastly, and perhaps most importantly, is the possibility that 563
remaining in a post-absorptive state for prolonged periods (i.e. fasting) may impart 564
independent health benefits beyond the established effects of the net negative energy balance 565
per se (and thus weight-loss). This is supported by Halberg et al. (47), who propose 566
significant improvements in insulin sensitivity in response to complete alternate-day fasting; 567
yet the failure of Soeters et al. (77) to replicate this finding with a near identical fasting 568
protocol renders current data equivocal. This conflict may be driven by methodological 569
contrasts in baseline adiposity and the refeeding protocol employed, but it leaves a pertinent 570
question nonetheless. If fasting-dependent effects on health do exist, are conventional meal 571
patterns contributing to metabolic disturbances irrespective of calorie content? This would 572
mean that changes in feeding times could constitute a novel dimension of what is considered 573
a healthy diet, as opposed to simply being a vehicle for calorie restriction. 574
In simple terms, nutritional considerations can be broadly classified under the three headings 575
of type, quantity and timing, with current dietary guidelines such as the Eatwell guide 576
(99,100) providing a very clear and evidenced illustration of the first two categories (i.e. what 577
foods we should eat and how much we should eat). Further research is needed to complete the 578
picture and include recommendations about when we should eat – or choose not to. 579
580
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